This paper is in the following e-collection/theme issue:

Digital Health Reviews (1289) Mobile Health (mhealth) (2939) Decision Support for Health Professionals (1185) Clinical Information and Decision Making (1407)

Published on in Vol 25 (2023)

Preprints (earlier versions) of this paper are available at https://preprints.jmir.org/preprint/43006, first published .
Applications of Federated Learning in Mobile Health: Scoping Review

Applications of Federated Learning in Mobile Health: Scoping Review

Applications of Federated Learning in Mobile Health: Scoping Review

Authors of this article:

Tongnian Wang1 Author Orcid Image ;   Yan Du2 Author Orcid Image ;   Yanmin Gong3 Author Orcid Image ;   Kim-Kwang Raymond Choo1 Author Orcid Image ;   Yuanxiong Guo1 Author Orcid Image
Article Authors Cited by (9) Tweetations (4) Metrics

    Review

    1Department of Information Systems and Cyber Security, The University of Texas at San Antonio, San Antonio, TX, United States

    2School of Nursing, The University of Texas Health Science Center at San Antonio, San Antonio, TX, United States

    3Department of Electrical and Computer Engineering, The University of Texas at San Antonio, San Antonio, TX, United States

    Corresponding Author:

    Yuanxiong Guo, PhD

    Department of Information Systems and Cyber Security

    The University of Texas at San Antonio

    1 UTSA Circle

    San Antonio, TX, 78249

    United States

    Phone: 1 210 458 8028

    Email: yuanxiong.guo@utsa.edu


    Background: The proliferation of mobile health (mHealth) applications is partly driven by the advancements in sensing and communication technologies, as well as the integration of artificial intelligence techniques. Data collected from mHealth applications, for example, on sensor devices carried by patients, can be mined and analyzed using artificial intelligence–based solutions to facilitate remote and (near) real-time decision-making in health care settings. However, such data often sit in data silos, and patients are often concerned about the privacy implications of sharing their raw data. Federated learning (FL) is a potential solution, as it allows multiple data owners to collaboratively train a machine learning model without requiring access to each other’s raw data.

    Objective: The goal of this scoping review is to gain an understanding of FL and its potential in dealing with sensitive and heterogeneous data in mHealth applications. Through this review, various stakeholders, such as health care providers, practitioners, and policy makers, can gain insight into the limitations and challenges associated with using FL in mHealth and make informed decisions when considering implementing FL-based solutions.

    Methods: We conducted a scoping review following the guidelines of PRISMA-ScR (Preferred Reporting Items for Systematic Reviews and Meta-Analyses Extension for Scoping Reviews). We searched 7 commonly used databases. The included studies were analyzed and summarized to identify the possible real-world applications and associated challenges of using FL in mHealth settings.

    Results: A total of 1095 articles were retrieved during the database search, and 26 articles that met the inclusion criteria were included in the review. The analysis of these articles revealed 2 main application areas for FL in mHealth, that is, remote monitoring and diagnostic and treatment support. More specifically, FL was found to be commonly used for monitoring self-care ability, health status, and disease progression, as well as in diagnosis and treatment support of diseases. The review also identified several challenges (eg, expensive communication, statistical heterogeneity, and system heterogeneity) and potential solutions (eg, compression schemes, model personalization, and active sampling).

    Conclusions: This scoping review has highlighted the potential of FL as a privacy-preserving approach in mHealth applications and identified the technical limitations associated with its use. The challenges and opportunities outlined in this review can inform the research agenda for future studies in this field, to overcome these limitations and further advance the use of FL in mHealth.

    J Med Internet Res 2023;25:e43006

    doi:10.2196/43006

    Keywords

    decision supportdistributed systemsfederated learninghealth monitoringmHealthprivacy 


    Background

    Mobile health (mHealth) generally refers to the use of mobile and wearable devices (eg, smartphones and smartwatches) in a health care setting [1]. In mHealth, health care–related data are typically collected from digital devices, such as biomedical sensors attached to the user’s body or portable devices with relevant applications installed [1]. More recently, there has been significant interest in using mHealth technologies for the collection of patient-reported outcome measures as such measures can enhance communication between patients and health care providers [2]. Additionally, machine learning (ML) techniques have been used to enhance diagnostic precision and facilitate remote, fine-grained, and high-quality health care in the mHealth field [3-5]. However, the traditional approach of training ML models requires centralized datasets, where a central server has access to the data of all patients. This can create privacy concerns for patients who may not want to share their personal information, and the regulatory requirements within the health care industry may also limit the sharing of sensitive information [6]. As a result, this leads to the existence of data silos, which will limit the use of traditional ML-based solutions. Furthermore, the limitations on data availability caused by privacy concerns and data silos can impede the implementation of large-scale health care systems, introducing biases in ML-based approaches. Consequently, these challenges can exacerbate the existing health disparities [7].

    Federated learning (FL) is a potential solution for mitigating the above-discussed challenges associated with sharing of raw patient data in mHealth applications. FL is a ML approach where the trained model parameters, rather than the raw data, are shared during the learning process [8]. FL-based methods typically involve a central server that holds a global model, and during each round of FL, a random subset of users is chosen to participate in the training of the global model. The selected users train the models locally using their data and then send their trained models back to the server. The server then aggregates the models and updates the global model, and the process repeats for subsequent FL rounds. However, it is worth noting that most existing FL frameworks in the health care domain are not designed to support data from mobile and wearable devices, which are increasingly important sources of data, given their widespread usage [9].

    Objective

    Although FL is a viable tool to support privacy-preserving health care decision-making, its implementation in clinical practice is not straightforward and has several limitations. Therefore, this scoping review aims to explore the current progress of FL-based mHealth applications (eg, how can FL be used to deal with sensitive, unbalanced, and heterogeneous data across users’ mobile devices?). Furthermore, this review discusses the associated limitations and challenges, providing health care professionals and policy makers with essential information for informed decision-making regarding the adoption of FL-based solutions in healthcare.

    In summary, this review seeks to achieve the following objectives: (1) present an overview of FL applications in mHealth settings, (2) assist practitioners and policy makers in understanding the challenges of implementing FL in mHealth settings, and (3) explore and identify potential approaches for developing efficient, effective, and robust FL systems for mHealth applications.


    Overview

    This scoping review was prepared and reported according to the guidelines of the PRISMA-ScR (Preferred Reporting Items for Systematic Reviews and Meta-Analyses Extension for Scoping Reviews) framework [10].

    Data Sources and Search Strategy

    Our literature search was conducted using several databases, such as PubMed, JMIR, Web of Science, IEEE Xplore, ACM Digital Library, ScienceDirect, and Springer, for articles published between January 2015 and January 2022. The initial search was carried out using keyword combinations such as “federated learning” AND “mobile” AND “health*” to identify papers published between January 2016 and January 2022 in all 7 databases. The abstract was used to extract the necessary information and avoid selection bias. A second search was also carried out using keyword combinations, such as “collaborative learning” AND mobile AND health* to identify articles published between January 2015 and January 2018 in PubMed, JMIR, Web of Science, IEEE Xplore, and ACM Digital Library. This second search was conducted because FL was first coined by Google in 2016, and collaborative learning was the predecessor and used interchangeably with FL. The details of the search results for each search engine are presented in Multimedia Appendix 1.

    Inclusion and Exclusion Criteria

    This study focuses on the use of FL in mHealth rather than the broader eHealth settings. Specifically, it examines how FL can be used with data captured by mobile devices to solve real-world health care problems. As such, articles that developed new FL techniques but were not specifically designed for mHealth applications were excluded. Additionally, only articles published in refereed journals and conference proceedings were considered, whereas other types of publications, such as conference abstracts only, books, editorials, and commentaries were excluded.

    Study Selection

    The study selection process involved the retrieval of 1095 publications through a database search, followed by the removal of 529 studies using the content-type filter in each database and 32 duplicate studies. Out of the remaining 534 studies, 487 were excluded after title and abstract screening, resulting in only 47 relevant articles. A final screening process was conducted, and 26 of the 47 articles were found to meet the inclusion criteria and included in the review. Two authors independently screened the titles and abstracts of the identified studies to determine their eligibility for this scoping review based on the above inclusion and exclusion criteria. Minor disagreements between the reviewers were resolved, and the reviewers reached an agreement. The process of study selection is illustrated in Figure 1.

    Figure 1. PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-Analyses) 2020 flow diagram of the study selection process.

    Search Results

    Of the 1095 articles located, only 26 were chosen for further analysis. These 26 publications were categorized into the following 2 themes: remote monitoring and diagnostic and treatment support based on their potential applications in mHealth. The 2009 United Nations Foundation and Vodafone Foundation report [11] presented 7 application categories within the mHealth field, and our included studies are related to 2 of these areas that are remote monitoring and diagnostic and treatment support. Hence, the included papers were separated into these 2 categories.

    Applications and Type of Data Used

    In mHealth settings, 1 application area of FL is remote monitoring, which includes monitoring self-care abilities, health status, and progression of chronic diseases. Twelve of 26 studies specifically focus on recognizing human activities using mobile sensors with FL, with a focus on distinguishing different activities of daily living (ADLs), such as walking, sitting, and standing. Recognizing ADLs is particularly useful for monitoring senior citizens’ self-care abilities and health status [5]. Two studies investigated the potential of using mobile sensor signals to monitor Parkinson disease by analyzing specific activities, such as arm droop, balance, and gait [12,13]. It was also noted that patients with Parkinson disease frequently experience freezing of gait, which can be easily detected in their daily activities [14]. Another disease that can be monitored in daily life is epilepsy. For example, Gong et al [15] used a data set comprising electrocorticography recordings of patients with epilepsy to facilitate the monitoring of such patients in their daily activities. Three studies [16-18] demonstrated the use of FL in monitoring stress using data collected from mobile devices during certain activities. Two types of data commonly used in these studies are electrocardiograms (ECGs) and electrodermal activity. Additionally, 3 other studies [19-21] proposed FL-based systems for cardiac health monitoring. For instance, Raza et al [21] designed an FL framework for ECG monitoring, which has the ability to effectively classify various arrhythmias. Furthermore, the authors incorporated an explainable artificial intelligence–based module on top of the classifier to ensure the interpretability of the classification results, thereby enabling clinical practitioners to better understand the prediction results. There are various other applications as well. Gong et al [22], experimentally evaluated their proposed collaborative learning scheme on diabetes data set and demonstrated its practicality for mHealth monitoring scenarios. Siddiqui et al [23] integrated FL with the Internet of Medical Things architecture to detect the risk of obesity in individuals. BMI data were analyzed to assess the obesity risk, and expert recommendations were generated based on the results.

    Another common application area is diagnostic and treatment support. For example, the diagnosis of mental health disorders currently relies heavily on the subjective judgment of the doctor through communication with patients and the responses from the patient health questionnaires [9]. In this regard, Xu et al [9] proposed a federated depression detection method. The evaluations were conducted in a hospital setting, with participants each receiving a smartphone to collect data on keyboard usage during specific sessions. Additionally, data from participants’ weekly tests, such as the Hamilton Depression Rating Scale [24] and the Young Man Mania Scale [25], were also collected. There have also been efforts to use FL for detecting skin diseases [26,27], and other medical conditions, such as cancer [28]. For example, Wu et al [27] developed an on-device federated contrastive learning framework for dermatological disease diagnosis with limited labels. Guo et al [28] proposed an FL-based system and experimented on a breast cancer data set by simulating mobile scenarios and demonstrating the potential of future mHealth applications for cancer detection. Moreover, Sun et al [29] proposed an FL framework for perioperative complications prognostic prediction, which demonstrates the potential of FL in providing treatment support. The proposed framework was tested using experiments on a real-world mHealth data set and the results suggested the utility of the proposed framework. A summary of the applications can be found in Table 1.

    Most of the studies (14 of 26) used human activity recognition data sets, often collected using smartphones and smartwatches. The Inertial Measurement Unit, which comprises accelerometers, gyroscopes, and magnetometers, is another commonly used sensor type in activity recognition. The most common data types for ADLs recognition are acceleration, angular velocity, and magnetometer. In studies on Parkinson disease, acceleration data is used to detect freezing of gait as it is a symptom unique to individuals with the condition [13]. Moreover, a data set is used by Chen et al [12] to record acceleration and angular velocity during various activities, such as arm droop, balance, gait, postural tremor, and resting tremor. Other medical conditions, such as epilepsy, can also be detected through activity monitoring, with electrocorticography being used to classify patients with epilepsy [15]. Other data types, such as ECG, electrodermal activity, blood volume pulse, and body temperature, can be used to monitor stress [16-18], cardiac health [19-21], and related conditions. Skin disease or breast cancer detection often relies on the analysis of disease-related images [26-28]. Detailed information about the data sets and data types used in the included studies can be found in Multimedia Appendix 2.

    Table 1. Applications of federated learning in mobile health.
    Areas and applicationsStudies
    Remote monitoringa



    		Activities of daily living

    		[4,12,13,30-38]

    		Parkinson disease[12,13]

    		Epilepsy[15]

    		Diabetes[22]

    		Cardiac health[19-21]

    		Obesity[23]

    		Stress[16-18]
    Diagnostic and treatment supportb



    		Depression [9]

    		Dermatological disease[26,27]

    		Cancer[28]

    		Perioperative complications[29]

    aRemote monitoring allows individuals to self-monitor their health status and manage the progression of chronic diseases from a remote location, such as their own home.

    bDiagnostic and treatment support refers to the provision of assistance for the diagnosis and treatment of patients from a remote location.

    Challenges for FL-Based Applications in mHealth Settings

    Overview

    The use of FL in mHealth settings is not without challenges, and examples include statistical heterogeneity, system heterogeneity, expensive communication, privacy leakage, and real-time data stream. These challenges were chosen for analysis because statistical heterogeneity, system heterogeneity, and expensive communication are FL-specific challenges, whereas real-time data stream is a crucial aspect of real-world mHealth applications. Table 2 provides a summary of the challenges identified in the selected studies. It should be noted that data scarcity and scalability are also challenges identified in the selected papers, but they are not specific to FL or mHealth, and therefore, will not be discussed further in this paper.

    Table 2. Challenges for federated learning (FL)–based applications in mobile health.
    ChallengesDescriptionReferences
    Statistical heterogeneityUsers’ data can be highly nonidentically distributed, characterized by diverse, imbalanced, and heterogeneous patterns, which can pose challenges for training models.[4,12,16,18,21,30,31,34-38]
    Expensive communicationAn increase in the number of devices participating in an FL system would result in an increase in the number of global communication rounds, as well as the size of the transmitted messages in each round (ie, communication is typically slower than local computation in FL).[4,9,12,13,15,20,21,26-28,30,32,34-38]
    System heterogeneityThe storage, computational, and communication capabilities of each device may differ due to variability in hardware and network connectivity, leading to system incompatibility.[16,34,35]
    Privacy leakageCommunicating model updates throughout the training process can nonetheless reveal sensitive information, so the privacy of FL needs to be enhanced.[12,15,16,21,22,28,29,33,37,38]
    Real-time data streamSensing measurements are generated continuously, and the FL process should be working continuously with new emerging data.[9,21,23,35,36,38]
    Data scarcityLabeled data are usually limited because it is costly and time-consuming to obtain labeling feedback regarding sensing data.[21,22,33,34]
    ScalabilityAs the amount of data available for training and the complexity of models increase, the resources required to train and run these models also increase.[17,20,33,38]
    Statistical Heterogeneity

    In typical FL systems, a significant number of user devices, such as smartphones, tablets, and smartwatches are used. These devices frequently generate and collect data in a nonidentically distributed (non-IID) manner, which can negatively impact the accuracy of the FL-based approach. Moreover, users’ data patterns are diverse, imbalanced, and heterogeneous, particularly when data recorded during user activities are considered.

    Expensive Communication

    In large-scale FL systems, the use of numerous user devices necessitates multiple rounds of global communication between users and the server. This can significantly impact the performance of the FL system, especially in resource-constrained environments such as mobile networks or Internet of Things devices [39]. This reinforces the importance of developing communication-efficient methods within FL systems, which aim to exchange minimal information as part of the training process, in order to reduce the communication cost of the system.

    System Heterogeneity

    In FL networks, the storage, computational, and communication capabilities of each device can vary widely due to diversity in hardware and network connectivity (eg, device types, operating systems, and storage capacity) [39]. These system-related constraints can result in system incompatibility due to data formats and there is a risk that only a small fraction of devices will be active in a federated network at any one time, or active devices may drop out at a given iteration [40]. As a result, system heterogeneity can have a considerable impact on the performance of FL-based approaches in practice.

    Privacy Leakage

    Although FL is intended to mitigate privacy concerns associated with conventional ML-based applications by only sharing model updates, such as gradient information instead of raw data, the communication of model updates throughout the training process may still reveal sensitive information, either to a third party or the central server [41]. Attempts have been made to design tools to enhance the privacy of FL using secure multiparty computation (SMC) [42] and differential privacy (DP) [41,43]. However, these methods can be costly and may negatively impact model performance or system efficiency [40]. Therefore, balancing the tradeoffs between privacy and performance is a significant challenge in the practical implementation of FL-based systems.

    Real-Time Data Stream

    Real-time data, such as sensing measurements, commonly occur in mHealth settings. Consequently, when using FL in mHealth settings, the FL model must be able to respond instantaneously to adjustments and updates in sensor data. In other words, the FL process must be able to operate continuously with incoming data streams in real-time to ensure that the model can adapt to and make predictions based on the most recent data.

    Solutions to Address Challenges

    Overview

    In the following paragraphs, we will provide an in-depth analysis of how the identified challenges can be overcome based on the findings from the articles included in our review (see Table 3). A summary of the included studies can be found in Multimedia Appendix 3.

    Table 3. Solutions for addressing the challenges of federated learning–based applications in mHealth.
    Challenges and solutionsReferences
    Statistical heterogeneity

    		Meta-learning[4]

    		Model personalization[12,18,21,30,36]

    		User clustering[34,35,37]

    		Adaptive update scheme[16,31,38]
    Expensive communication

    		FedAvg[4,9,12,13,20,26,27,30,36]

    		Flexible local updates[15,37,38]

    		Compression schemes[21,28,32,34,35]
    System heterogeneity

    		Active sampling[16]

    		Fault tolerance[34,35]
    Privacy leakage

    		Differential privacy[28,38]

    		Homomorphic encryption[12,15,22,37]

    		Strict information sharing scheme[16,21,29]

    		2-stage privacy-preserving scheme[33]
    Real-time data stream

    		Incremental learning[36]

    		Web-based learning[38]

    		Repeat working with continuously emerging data[9,21,23]

    		Periodical update[35]
    Statistical Heterogeneity

    Twelve of the included studies addressed the challenge of statistical heterogeneity. For example, Ek et al [30] empirically evaluated 3 FL algorithms (ie, FedAvg [8], FedPer [44], and FedMA [45]) to determine their effectiveness. Findings from their evaluations suggested that the averaging of more personalized models leads to performance degradation when the learned global model is used for evaluation on the test set. Several studies have attempted to address this challenge by designing personalized FL methods for adapting global models for individual clients.

    One possible approach is meta-learning, specifically the federated representation learning framework proposed by Li et al [4]. This framework used a signal embedding network, that is meta-trained in an FL manner and the learned signal representations were further fed into a personalized classification network for better activity prediction for each user. One of the most common approaches is model personalization, in which base layers and personalization layers are trained separately. For instance, in Chen et al’s [12] and Raza et al’s [21] studies, transfer learning was applied to learn personalized models for each user, as the higher layers aim at learning more user-specific features whereas the lower layers focus on learning common and transferable features. Furthermore, Liu et al [18] added a simple user embedding to the neural network, which was kept only on that user’s device. Wu et al [36] proposed a generative convolutional autoencoder network and fine-tuned the model parameters of higher layers of generative convolutional autoencoder to obtain more accurate personalized models. Another way to address statistical heterogeneity is user clustering, which enables the FL system to capture the underlying relationships between users as studied by Ouyang et al [34] and Tu et al [35]. By clustering users, those in the same group can collaboratively learn personalized models. Similarly, Xiao et al [37] designed a feature extractor capable of identifying and extracting the local features and global relationships from heterogeneous data to address statistical heterogeneity.

    In addition to the abovementioned methods, several studies attempted to address statistical heterogeneity by designing update schemes to guarantee convergence for non-IID data. Traditional FL methods may diverge when the data are not identically distributed across devices, particularly when the chosen devices perform too many local updates [40]. Accordingly, Yu et al [38] derived a personalized strategy for semisupervised learning users who require personalized service. Specifically, the personalized models will be initialized using the general model downloaded from the server and users will additionally convey gradients to the server once during each training iteration to obtain personalized models. Gudur and Perepu [31] introduced a 2-version FL framework for addressing heterogeneity issues in non-IID scenarios by leveraging overlapping information gained across activities—one using model distillation update and the other using weighted update. Additionally, Zhang et al [16] developed a new local update scheme and an adaptive global update scheme, which jointly enable each device to decide the optimized local and global update strategies to deal with the non-IID problem.

    Communication Efficiency

    Of the 26 studies, 17 studies addressed the challenge of expensive communication. Among them, 9 studies [4,9,12,13,20,26,27,30,36] used the FedAvg algorithm [8] to reduce communication overhead, as FedAvg [8] is frequently adopted as a method to reduce the number of required communication rounds. In addition, Xiao et al [37] proposed a system that only calculates and circulates the average weights after receiving the model weights from a certain number of connected users in order to improve communication efficiency. Yu et al [38] developed an unsupervised gradients aggregation strategy together with FedAvg to decrease the communication overhead. Moreover, Gong et al [15] proposed a scheme based on the alternating direction method of multipliers [46] to decompose the logistic regression model into smaller subproblems that can be locally computed and reduce communication cost.

    The previously mentioned studies focus on developing optimization methods that enable flexible local updates, thereby reducing the overall number of communication rounds. However, the model compression scheme can also ensure communication efficiency by significantly decreasing the amount of information communicated in each round. Notably, there are various methods for achieving this. For instance, Liu et al [32] developed a collaborative privacy-preserving learning system that mainly considered 2 different parameter exchange protocols—round-robin and asynchronous—both of which aim to ensure low communication cost. Ouyang et al [34] designed a learned cluster structure for their system, which allows the use of clusterwise straggler dropout and correlation-based node selection to reduce communication overhead. Moreover, Tu et al [35] proposed FedDL, which can reduce the number of parameters communicated between users and the server through a dynamic layerwise sharing scheme. This is because only the lower layers of local models need to be uploaded to the server for global training. In separate work, Raza et al [21] designed a framework for ECG monitoring and proposed a new method called layer selection, which can significantly reduce the overall communication cost. In addition to the aforementioned methods, Guo et al [28] offloaded health monitoring and model training tasks to private servers of hospitals with strong computing resources to reduce communication cost and protect the privacy of users.

    System Heterogeneity

    Three of the studies focused on system heterogeneity. For instance, Ouyang et al [34] leveraged the inherent relationships between users to dynamically drop nodes during the FL process, where the server will drop users who converge slower than others within the same cluster or are less related to others in the same cluster. Tu et al [35] used the similarity among users’ model weights to learn the layerwise sharing structure, which can be regarded as an asynchronous scheme that mitigates the impact of straggling users in heterogeneous environments. Furthermore, as proposed by Zhang et al [16], the bottom-up design of the new local update scheme and the adaptive global update scheme allows the FL system to meet device-specific optimization goals (eg, energy savings) while strictly protecting user privacy.

    Privacy Leakage

    In the studies analyzed, 10 of them tackled the issue of privacy leakage that may arise when implementing FL in real-world scenarios. There are 3 main ways to protect data privacy in the FL framework [40], which are as follows: SMC [42], DP [41,43], and homomorphic encryption [47]. Four of these studies [12,15,22,37] used homomorphic encryption to avoid information leakage. Two studies adopted DP. Specifically, Yu et al [38] leveraged DP in combination with the Byzantine-robust aggregation rule [48] to defend against malicious clients and prevent data recovery attacks, whereas Guo et al [28] proposed 2-stage strong privacy protection based on DP to resist both external and internal security risks. Other novel methods were also proposed. A 2-stage privacy-preserving scheme was developed [33] to deliver great recovery resistance to maximum a priori estimation attacks. Zhang et al [16] designed an abnormal health detection system that strictly prohibited any violations to meet the privacy requirements and the only information allowed to be sent to the server is the weight updates generated by locally trained models on each device. Raza et al [21] proposed a solution to enhance privacy by only sharing weights that contain more common and low-level (ie, less private) features. Sun et al [29] proposed a solution where the training process will not reveal any information due to the masked weighted sum, which was uploaded by users and would not cause information leakage.

    Real-time Data Stream

    Six of the studies considered the use of real-time data in mHealth. For example, 3 of these studies [9,21,23] developed methods that can continuously adapt to new emerging data by repeating the entire process with the accumulation of new data. Several studies developed specific methods or used unique data sources to address this issue. More specifically, the system proposed by Tu et al [35] can periodically update the layerwise sharing structure and models to deal with users’ dynamic data distribution. Yu et al [38] let unlabeled users be trained with the online learning method so that the proposed system can use only a small number of labeled users with limited samples to train a model with competitive performance along with the massive real-time stream sensing data produced by unlabeled users. The framework proposed in reference [36] was able to perform incremental learning [49], where both the cloud model and user models can be continuously updated when new user data is encountered. Furthermore, the learned cloud model that captures the generic information from users can be easily deployed as a previous model for new users.


    Principal Findings

    To advance the understanding of the use of FL in mHealth, a scoping review of 26 published studies was conducted. The results of this review indicated that FL, a relatively new privacy-preserving method shows great promise for use in mHealth. The reason for this is that medical data often resides in isolated data silos, and privacy concerns can restrict access to this data. Without access to sufficient data, conventional ML is limited in its utility. FL offers a solution by supporting collaborative model training on data from different sources while preserving privacy. Additionally, the results of this scoping review identify the potential application domains for FL in mHealth and the challenges that must be addressed to fully realize its potential. Furthermore, the review highlights potential approaches to addressing these challenges and improving the effectiveness of FL in mHealth applications.

    The first aim of this review is to summarize the applications of FL systems in mHealth. The findings indicate that FL can be used for remote monitoring and diagnostic and treatment support within the mHealth field. More specifically, it can be applied to address a wide range of real-world problems, such as Parkinson disease monitoring, cardiac health monitoring, and mental health disorders diagnosis. When using FL in mHealth, various types of sensor data can be collected, including acceleration, angular velocity, magnetometer, ECG, and temperature data, to address different problems.

    In other words, FL is a paradigm shift from centralized data lakes, and the use of FL in mHealth has a significant impact on various stakeholders, including patients, clinicians, and health care providers. By implementing large-scale FL-based applications in mHealth, patients can benefit from improved clinical decision-making without having to compromise their privacy. With such systems, patients can receive better care even from their own homes, particularly for those with rare or geographically uncommon diseases. More importantly, the adoption of FL in mHealth can improve patient privacy and lower the hurdle to becoming a data donor. For clinicians and practitioners, using FL-based systems in mHealth can augment their expertise with knowledge from larger populations [50]. This can help to mitigate the issue of bias in clinical practice that occurs when clinicians are exposed to a subgroup of the population based on their location and demographic environment, which can lead to inaccurate assumptions about the probability of certain diseases or their interconnection [50]. By using FL-based systems, clinicians can ensure a consistency of diagnosis that is not currently attainable, improving the quality of care for patients. For hospitals, policy makers and health care providers, the stabilization of federated-based systems for mHealth can offer better services for diverse population groups without worrying about patient privacy concerns. In FL-based systems, patients can maintain full control and possession of their data with limited risk of misuse by third parties, which makes it a more secure and trustworthy option for patients.

    Additionally, this scoping review aims to provide practitioners, policy makers, and health care providers with a comprehensive understanding of the challenges associated with using FL in mHealth. The review specifically focuses on issues, such as expensive communication overhead, statistical heterogeneity, system heterogeneity, privacy leakage, and real-time data stream. This review provides an in-depth examination of these challenges and highlights the potential effects they could have on FL systems implemented in real-world settings. Through the review, practitioners and policy makers can gain insight into the unique characteristics of implementing FL in mHealth and use those insights to make informed decisions when designing, implementing, and evaluating FL systems in mHealth.

    This review’s final goal is to identify potential solutions that can be applied to address various challenges associated with the use of FL in mHealth applications. One of the main challenges identified in the literature is high communication cost, which can be addressed through methods, such as FedAvg and model compression schemes. Another major challenge is statistical heterogeneity, which can lead to significant performance degradation in FL systems that use traditional aggregation methods, such as FedAvg as this approach is sensitive to heterogeneous and imbalanced data distributions among users, resulting in decreased model performance. This highlights the need for more robust and personalized FL approaches that can adapt to the unique characteristics of each user’s data distribution. Data security is also a significant concern in FL for mHealth, and many studies have proposed the use of additional privacy protection mechanisms, such as DP and SMC. However, these mechanisms often result in reduced model performance or system efficiency [51], highlighting the need for further research to balance the trade-offs between privacy and system performance. Additionally, this review identifies system heterogeneity as another challenge in FL for mHealth, but to date, only a limited number of studies addressed this issue. In summary, further research is necessary to tackle these prevalent challenges and improve the performance of FL systems.

    Limitations

    This review has several limitations. First, this review focused on 5 key challenges related to applying FL, whereas other challenges like data scarcity and scalability were not discussed due to page limit. Second, while the search period covered several years, the majority of the included studies were from 2020 to 2021. This could be due to the fact that FL was first introduced by Google in 2016, which has led to an increase in research on this topic in recent years. Fortunately, this allows for a more current understanding of FL’s development and impact on mHealth, and it is expected that more studies will be published in the coming years. Furthermore, for the paper collection process, the search terms should have certain limitations and were not able to include all relevant studies. However, the studies that were gathered through our data sources and search strategy should provide a comprehensive overview of the field.

    Conclusions

    This scoping review provides valuable insights for different stakeholders on the potential benefits and challenges of using FL in mHealth. FL is a novel and efficient privacy-preserving learning method that can be applied in a wide range of fields, particularly in mHealth, where it has been proposed for various applications such as Parkinson disease monitoring, cardiac health monitoring, and mental health disorder diagnosis. However, many barriers prevent practitioners from effectively implementing FL in mHealth. The most common obstacles include communication costs, statistical and system heterogeneity, and privacy leakage. Policy makers and health care providers need to consider these challenges when designing and implementing FL systems. This will help them to provide better services and support for health professionals, patients, patients’ families, the public, and other relevant parties. Further research is needed to address these common challenges and improve the performance of FL systems.

    Acknowledgments

    The work of Y Guo was partially supported by National Science Foundation under grants CNS-2106761 and CMMI-2222670. The work of Y Gong was supported in part by the US National Science Foundation under grant CNS-2047761. “This project was funded (full or in-part) by The University of Texas at San Antonio, Office of the Vice President for Research, Economic Development, and Knowledge Enterprise.”

    Conflicts of Interest

    None declared.

    Multimedia Appendix 1

    Search strategy and search results for different databases.

    DOCX File , 19 KB
    Multimedia Appendix 2

    Summary of datasets used in the selected studies.

    DOCX File , 20 KB
    Multimedia Appendix 3

    Summary of the selected studies.

    DOCX File , 38 KB
    1. Adibi S, editor. Mobile Health: A Technology Road Map. Cham: Springer; 2015.
    2. Hauth F, Bizu V, App R, Lautenbacher H, Tenev A, Bitzer M, et al. Electronic patient-reported outcome measures in radiation oncology: initial experience after workflow implementation. JMIR Mhealth Uhealth 2019;7(7):e12345 [FREE Full text] [CrossRef] [Medline]
    3. Liu Z, Li X, Peng H, He L, Yu PS. Heterogeneous similarity graph neural network on electronic health records. 2020 Presented at: 2020 IEEE International Conference on Big Data (Big Data); December 10-13, 2020; Atlanta, GA. [CrossRef]
    4. Li C, Niu D, Jiang B, Zuo X, Yang J. Meta-HAR: federated representation learning for human activity recognition. 2021 Presented at: Proceedings of the Web Conference; April 19-23, 2021; New York   URL: https://doi.org/10.1145/3442381.3450006 [CrossRef]
    5. Zhu H, Samtani S, Brown R, Chen H. A deep learning approach for recognizing activity of daily living (ADL) for senior care: exploiting interaction dependency and temporal patterns. Manag Inf Syst Q 2021;45(2):859-896. [CrossRef]
    6. Anderson CL, Agarwal R. The digitization of healthcare: boundary risks, emotion, and consumer willingness to disclose personal health information. Inf Syst Res 2011;22(3):469-490. [CrossRef]
    7. Panch T, Mattie H, Atun R. Artificial intelligence and algorithmic bias: implications for health systems. J Glob Health 2019;9(2):010318 [FREE Full text] [CrossRef] [Medline]
    8. McMahan B, Moore E, Ramage D, Hampson S, Arcas BA. Communication-efficient learning of deep networks from decentralized data. 2017 Presented at: Proceedings of the 20th International Conference on Artificial Intelligence and Statistics; April 20-22, 2017; Ft. Lauderdale   URL: https://proceedings.mlr.press/v54/mcmahan17a.html [CrossRef]
    9. Xu X, Peng H, Bhuiyan MZA, Hao Z, Liu L, Sun L, et al. Privacy-preserving federated depression detection from multisource mobile health data. IEEE Trans Ind Inf 2021;18(7):4788-4797. [CrossRef]
    10. Tricco AC, Lillie E, Zarin W, O'Brien KK, Colquhoun H, Levac D, et al. PRISMA extension for scoping reviews (PRISMA-ScR): checklist and explanation. Ann Intern Med 2018;169(7):467-473 [FREE Full text] [CrossRef] [Medline]
    11. Vital Wave Consulting. mHealth for Development: The Opportunity of Mobile Technology for Healthcare in the Developing World. 2009.   URL: https:/​/reliefweb.​int/​report/​world/​mhealth-development-opportunity-mobile-technology-healthcare-developing-world [accessed 2023-04-03]
    12. Chen Y, Qin X, Wang J, Yu C, Gao W. FedHealth: a federated transfer learning framework for wearable healthcare. IEEE Intell Syst 2020;35(4):83-93. [CrossRef]
    13. Zhao Y, Haddadi H, Skillman S, Enshaeifar S, Barnaghi P. Privacy-preserving activity and health monitoring on databox. USA: Association for Computing Machinery; 2020 Presented at: Proceedings of the Third ACM International Workshop on Edge Systems, Analytics and Networking; April 27, 2020; Heraklion, Greece. [CrossRef]
    14. Bächlin M, Plotnik M, Roggen D, Maidan I, Hausdorff JM, Giladi N, et al. Wearable assistant for Parkinson's disease patients with the freezing of gait symptom. IEEE Trans Inf Technol Biomed 2010;14(2):436-446. [CrossRef] [Medline]
    15. Gong Y, Fang Y, Guo Y. Private data analytics on biomedical sensing data via distributed computation. IEEE/ACM Trans Comput Biol Bioinform 2016;13(3):431-444. [CrossRef] [Medline]
    16. Zhang DY, Kou Z, Wang D. FedSens: a federated learning approach for smart health sensing with class imbalance in resource constrained edge computing. 2021 Presented at: IEEE INFOCOM 2021 - IEEE Conference on Computer Communications; May 10-13, 2021; Vancouver. [CrossRef]
    17. Can YS, Ersoy C. Privacy-preserving federated deep learning for wearable IoT-based biomedical monitoring. ACM Trans Internet Technol 2021;21(1):1-17. [CrossRef]
    18. Liu JC, Goetz J, Sen S, Tewari A. Learning from others without sacrificing privacy: simulation comparing centralized and federated machine learning on mobile health data. JMIR Mhealth Uhealth 2021;9(3):e23728 [FREE Full text] [CrossRef] [Medline]
    19. Fang L, Liu X, Su X, Ye J, Dobson S, Hui P, et al. Bayesian inference federated learning for heart rate prediction. In: Ye J, O'Grady MJ, Civitarese G, Yordanova K, editors. Wireless Mobile Communication and Healthcare. Cham: Springer; 2021:116-130.
    20. Ogbuabor GO, Augusto JC, Moseley R, van Wyk A. Context-aware support for cardiac health monitoring using federated machine learning. In: Bramer M, Ellis R, editors. Artificial Intelligence XXXVIII. Cham: Springer; 2021.
    21. Raza A, Tran KP, Koehl L, Li S. Designing ECG monitoring healthcare system with federated transfer learning and explainable AI. Knowl Based Syst 2022;236:107763 [FREE Full text] [CrossRef]
    22. Gong Y, Fang Y, Guo Y. Privacy-preserving collaborative learning for mobile health monitoring. 2015 Presented at: IEEE Global Communications Conference (GLOBECOM); December 6-10, 2015; San Diego, CA. [CrossRef]
    23. Siddiqui S, Khan AA, Dev K, Dey I. Integrating federated learning with IoMT for managing obesity in smart city. : Association for Computing Machinery; 2021 Presented at: Proceedings of the 1st Workshop on Artificial Intelligence and Blockchain Technologies for Smart Cities with 6G; October 25-29, 2021; New Orleans, Louisiana. [CrossRef]
    24. Hamilton M. The Hamilton rating scale for depression. In: Sartorius N, Ban TA, editors. Assessment of Depression. Berlin: Springer-Verlag; 1986:143-152.
    25. Young RC, Biggs JT, Ziegler VE, Meyer DA. A rating scale for mania: reliability, validity and sensitivity. Br J Psychiatry 1978;133(5):429-435. [CrossRef] [Medline]
    26. Elayan H, Aloqaily M, Guizani M. Deep federated learning for IoT-based decentralized healthcare systems. 2021 Presented at: International Wireless Communications and Mobile Computing (IWCMC); June 28-July 2, 2021; Harbin City, China. [CrossRef]
    27. Wu Y, Zeng D, Wang Z, Sheng Y, Yang L, James AJ, et al. Federated contrastive learning for dermatological disease diagnosis via on-device learning (invited paper). 2021 Presented at: IEEE/ACM International Conference On Computer Aided Design (ICCAD); November 1-4, 2021; Munich, Germany. [CrossRef]
    28. Guo Y, Liu F, Cai Z, Chen L, Xiao N. FEEL: a federated edge learning system for efficient and privacy-preserving mobile healthcare. USA: Association for Computing Machinery; 2020 Presented at: 49th International Conference on Parallel Processing; August 17-20, 2020; Edmonton, Canada. [CrossRef]
    29. Sun W, Chen Y, Yang X, Cao J, Song Y. FedIO: bridge inner- and outer-hospital information for perioperative complications prognostic prediction via federated learning. 2021 Presented at: 2021 IEEE International Conference on Bioinformatics and Biomedicine (BIBM); December 9-12, 2021; Houston, TX, USA. [CrossRef]
    30. Ek S, Portet F, Lalanda P, Vega G. Evaluation of federated learning aggregation algorithms: application to human activity recognition. USA; 2020 Presented at: Adjunct Proceedings of the 2020 ACM International Joint Conference on Pervasive and Ubiquitous Computing and Proceedings of the 2020 ACM International Symposium on Wearable Computers; September 12-17, 2020; Virtual Event Mexico. [CrossRef]
    31. Gudur GK, Perepu SK. Resource-constrained federated learning with heterogeneous labels and models for human activity recognition. In: Li X, Wu M, Chen Z, Zhang L, editors. Deep Learning for Human Activity Recognition. Singapore: Springer; 2021:57-69.
    32. Liu M, Jiang H, Chen J, Badokhon A, Wei X, Huang MC. A collaborative privacy-preserving deep learning system in distributed mobile environment. 2016 Presented at: 2016 International Conference on Computational Science and Computational Intelligence (CSCI); 15-17 Dec, 2016; Las Vegas, NV, USA. [CrossRef]
    33. Lyu L, He X, Law YW, Palaniswami M. Privacy-preserving collaborative deep learning with application to human activity recognition. USA; 2017 Presented at: Proceedings of the 2017 ACM on Conference on Information and Knowledge Management; November 6-10, 2017; Singapore. [CrossRef]
    34. Ouyang X, Xie Z, Zhou J, Huang J, Xing G. ClusterFL: a similarity-aware federated learning system for human activity recognition. 2021 Presented at: Proceedings of the 19th Annual International Conference on Mobile Systems, Applications, and Services; Virtual Event Wisconsin; June 24-July 2, 2021. [CrossRef]
    35. Tu L, Ouyang X, Zhou J, He Y, Xing G. FedDL: federated learning via dynamic layer sharing for human activity recognition. 2021 Presented at: Proceedings of the 19th ACM Conference on Embedded Networked Sensor Systems; November 15-17, 2021; Coimbra, Portugal. [CrossRef]
    36. Wu Q, Chen X, Zhou Z, Zhang J. FedHome: cloud-edge based personalized federated learning for in-home health monitoring. IEEE Trans Mobile Comput 2020;21(8):2818-2832. [CrossRef]
    37. Xiao Z, Xu X, Xing H, Song F, Wang X, Zhao B. A federated learning system with enhanced feature extraction for human activity recognition. Knowl Based Syst 2021;229:107338. [CrossRef]
    38. Yu H, Chen Z, Zhang X, Chen X, Zhuang F, Xiong H, et al. FedHAR: semi-supervised online learning for personalized federated human activity recognition. IEEE Trans Mobile Comput 2021:1-1. [CrossRef]
    39. van Berkel CH. Multi-core for mobile phones. 2009 Presented at: Design,Automation Test in Europe Conference and Exhibition; April 20-24, 2009; Nice, France. [CrossRef]
    40. Li T, Sahu AK, Talwalkar A, Smith V. Federated learning: challenges, methods, and future directions. IEEE Signal Process Mag 2020;37(3):50-60. [CrossRef]
    41. McMahan HB, Ramage D, Talwar K, Zhang L. Learning differentially private recurrent language models. ArXiv :171006963 Preprint posted online on October 18, 2017. [FREE Full text]
    42. Bonawitz K, Ivanov V, Kreuter B, Marcedone A, McMahan H, Patel S, et al. Practical secure aggregation for privacy-preserving machine learning. USA; 2017 Presented at: Proceedings of the 2017 ACM SIGSAC Conference on Computer and Communications Security; October 30-November 3, 2017; Dallas, Texas. [CrossRef]
    43. Bhowmick A, Duchi J, Freudiger J, Kapoor G, Rogers R. Protection against reconstruction and its applications in private federated learning. ArXiv. Preprint posted online on December 3, 2018 2019:181200984 [FREE Full text]
    44. Arivazhagan MG, Aggarwal V, Singh AK, Choudhary S. Federated learning with personalization layers. ArXiv. Preprint posted online on December 2, 2019 2019:191200818 [FREE Full text]
    45. Wang H, Yurochkin M, Sun Y, Papailiopoulos D, Khazaeni Y. Federated learning with matched averaging. ArXiv. Preprint posted online on February 15, 2020 2020:200206440 [FREE Full text]
    46. Boyd S, Parikh N, Chu E, Peleato B, Eckstein J. Distributed Optimization and Statistical Learning via the Alternating Direction Method of Multipliers. Norwell: Now Publishers; 2011.
    47. Acar A, Aksu H, Uluagac AS, Conti M. A survey on homomorphic encryption schemes. ACM Comput Surv 2019;51(4):1-35. [CrossRef]
    48. Yin D, Chen Y, Kannan R, Bartlett P. Byzantine-robust distributed learning: towards optimal statistical rates. 2018 Presented at: Proceedings of the 35th International Conference on Machine Learning; July 10-15, 2018; Stockholm, Sweden   URL: https://proceedings.mlr.press/v80/yin18a.html
    49. Rebuffi SA, Kolesnikov A, Sperl G, Lampert CH. iCaRL: Incremental Classifier and Representation Learning. 2017.   URL: https:/​/openaccess.​thecvf.com/​content_cvpr_2017/​html/​Rebuffi_iCaRL_Incremental_Classifier_CVPR_2017_paper.​html [accessed 2022-05-05]
    50. Rieke N, Hancox J, Li W, Milletarì F, Roth HR, Albarqouni S, et al. The future of digital health with federated learning. NPJ Digit Med 2020;3(1):119 [FREE Full text] [CrossRef] [Medline]
    51. Hu R, Guo Y, Li H, Pei Q, Gong Y. Personalized federated learning with differential privacy. IEEE Internet Things J 2020;7(10):9530-9539. [CrossRef]

    ADL: activity of daily living
    DP: differential privacy
    ECG: electrocardiogram
    FL: federated learning
    mHealth: mobile health
    ML: machine learning
    non-IID: nonidentically distributed
    PRISMA-ScR: Preferred Reporting Items for Systematic Reviews and Meta-Analyses Extension for Scoping Reviews
    SMC: secure multiparty computation

    Edited by T Leung; submitted 27.09.22; peer-reviewed by J Lin, S Marceglia; comments to author 01.12.22; revised version received 24.01.23; accepted 10.03.23; published 01.05.23

    Copyright

    ©Tongnian Wang, Yan Du, Yanmin Gong, Kim-Kwang Raymond Choo, Yuanxiong Guo. Originally published in the Journal of Medical Internet Research (https://www.jmir.org), 01.05.2023.

    This is an open-access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work, first published in the Journal of Medical Internet Research, is properly cited. The complete bibliographic information, a link to the original publication on https://www.jmir.org/, as well as this copyright and license information must be included.